V4070-PCB [EMMICRO]
Crypto Contactless Identification Device; 加密非接触式识别装置型号: | V4070-PCB |
厂家: | EM MICROELECTRONIC - MARIN SA |
描述: | Crypto Contactless Identification Device |
文件: | 总9页 (文件大小:170K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
EM MICROELECTRONIC-MARIN SA
V4070
Crypto Contactless Identification Device
Features
Typical Operating Configuration
•
•
•
•
•
On Chip Crypto-Algorithm
Two Way Authentication protocol
96 bits of Secret-Key in EEPROM (unreadable)
32 bits of fix Device Identification
30 bits of USER_MEMORY (UM) with read
access (OTP)
Secret-Key programmable via CID-Interface
Lock-Bits to inhibit programming
Data Transmission performed by Amplitude
Modulation
Coil 1
L
V4070
•
•
•
Coil 2
•
•
•
•
•
•
Bit Period = 32 periods of carrier frequency
200 pF on chip Resonant Capacitor (untrimmed)
-40 to +85°C Temperature range
115 kHz TO 135 kHz Field Frequency
On chip Rectifier and Voltage Limiter
No external supply buffer capacitance needed
due to low power consumption
Typical value of inductance at 125 KHz is 8 mH
Figure 1
Description
Pin Assignment
The V4070 is a CMOS integrated circuit intended for
use in electronic Read/Write RF Transponders. The
chip contains an implementation of a crypto-algorithm
with 96 Bits of user configurable secret-key contained
in EEPROM. It also provides a unique Device Identi-
fication of 32 Bits that can never be modified as well
as 30 Bits of freely programmable USER-MEMORY.
Bits 15 and 14 of word 1 are used as Lock-Bits. The
memory can only be accessed for writing or erasing if
these two bits have the contents «10» as when they
are delivered.
COIL 1
COIL 2
V4070
The V4070 transmits data to the transceiver by modu-
lating the amplitude of the electromagnetic field, and
receives data and commands in a similar way.
The coil of the tuned circuit is the only external com-
ponent required, all remaining functions are integrated
in the chip.
COIL1
COIL2
coil terminal / clock input
coil terminal
Figure 2
Applications
•
•
High security automotive immobilizer
High security hands-free access control
1
EM MICROELECTRONIC-MARIN SA
V4070
Absolute Maximum Ratings
Handling Procedures
This device has built-in protection against high static
voltages or electric fields; however, anti-static precau-
tions should be taken as for any other CMOS compo-
nent. Unless otherwise specified, proper operation can
only occur when all terminal voltages are kept within
the supply voltage range.
Parameter
Symb. Min.
Max. Unit
Supply voltage
Voltage at remaining
pins
Storage temp.
Operating temp.
Maximum AC peak
Current induced on
COIL1 and COIL2
VDD
-0.3
9.5
V
Vpin
VSS - 0.3 VDD + 0.3
V
Tstore
Top
-55
-40
125
85
°C
°C
ICOIL
-30
30
mA
Table 1
Stresses above these listed maximum ratings may
cause permanent damage to the device. Exposure
beyond specified electrical characteristics may affect
device reliability or cause malfunction.
System Principle
Transceiver
Transponder
Data to be sent
to transponder
Modulator
Coil 1
Antenna
Oscillator
Driver
V4070
Coil 2
Data
Decoder
Filter &
Gain
Demodulator
Data received
from transponder
RECEIVE MODE
READ MODE
Signal on
Transponder coil
Signal on
Transceiver coil
Signal on
Transceiver coil
Signal on
Transponder coil
RF Carrier
Data
RF Carrier
Data
Figure 3
2
EM MICROELECTRONIC-MARIN SA
V4070
Electrical Characteristics
Operating Conditions
VDD = 2.5V VSS = 0V
fcoil = 125 kHz Sine wave
Vcoil = 1Vpp
Top = 25°C
Parameter
Symbol
Conditions
Min.
Typ.
Max.
Unit
Supply voltage
VDD
Read Mode
2
1)
V
EEPROM write voltage
VEE
3
V
Supply current/read
Supply current/read/H
Supply current/write
Ird
IrdH
Iwr
Read Mode VDD=2.0V
Read Mode VDD=5.0V
Write Mode VDD=3.0V
-40°C<T<85°C
5
10
50
µA
µA
µA
Supply current/write/H
Modulator voltage drop
IwrH
VON
Write Mode VDD=5.0V
80
µA
V(Coil1-VSS) & V(Coil2-VSS)
0.5
V
Icoil = 100µA
V(Coil1-VSS) & V(Coil2-VSS)
Icoil = 5mA
2.5
V
Resonance capacitor
Capacitor temp. coeff
Capacitor tolerance/wafer
POR level high
Cr
170
-75
-2
200
2.2
230
75
2
pF
ppm/K
%
TKCr
TOLCr
Vprh
-40°C to 85°C
Rising supply
2.8
V
Clock extractor input min.
Clock extractor input max.
MONOFLOP delay
Vclkmin Min for clock extraction
Vclkmax Max for clock extraction
Tmono
1
Vpp
mVpp
µs
50
80
40
1000
10
EEPROM data endurance
EEPROM retention
Ncy
Tret
Erase all / Write all
cycles
years
Top = 55°C after 1000
cycles
1) Maximum voltage is defined by forcing 10mA on Coil1-Coil2
Table 2
Timing Characteristics
Parameter
Power on Reset Time
Symbol
Conditions
RF periods
Value
600
Unit
µs
tpor
Read Bit Period
LIW/ACK/NACK pattern
Duration
trdb
32
periods
tpatt
trID
RF periods
RF periods
160
1024
periods
periods
Duration of ID
Divergence-Time
Tdiv
RF periods
224
periods
Authentication-Time
WRITE Access Time
EEPROM write Time
tauth
twa
twee
RF periods
RF periods
RF periods, VDD = 3V
3744
128
3072
periods
periods
periods
Table 3
RF periods respresent periods of the carrier frequency emitted by the transceiver unit. For example, if 125 kHz
is used, the Read bit period would be: 1/125’000*32 = 256µs.
3
EM MICROELECTRONIC-MARIN SA
V4070
Block Diagram
Serial Data
Modulator
Encoder
+V
Coil 1
Coil 2
AC/DC
converter
Power
Control
Cr
Cs
Reset
GND
Write Enable
Clock
Extractor
Sequencer
Control
Logic
Crypto-
Algorithm
EEPROM
Command
Decoder
Data
Extractor
Figure 4
Pad Description
Functional Description
General
Pad
Name
Description
Coil Terminal 2
Negative DC Supply
Test 1 connection
Test 2 connection
Test 3 connection
Positive DC Supply
Coil Terminal 1
The V4070 is supplied by means of an electromag-
netic field induced on the attached coil. The AC volt-
age is rectified in order to provide a DC internal supply
voltage. When the DC voltage crosses the Power-On
level, the chip will enter the Standby Mode and expect
commands. In Standby Mode a continuous sequence
of Listen Windows (LIW) is generated. During this time,
the crypto-Chip will turn to the Receive Mode (RM) if it
receives a valid RM pattern. The chip then expects a
command to enter the desired mode of operation.
1
3
4
5
6
7
8
COIL2
VSS
TST1
TST2
TST3
VDD
COIL1
Memory Organisation
The 160 bits EEPROM are organised in 10 words of
16 bits. Words 0 and 1 contain the USER_MEMORY
and the Lock-Bits LB1 and LB0. Write-Mode can only
be entered if LB1=’1' and LB0=’0'. Words 2 and 3 con-
tain the ID that can never be modified. Words 4 through
9 contain the 96 bits of secret key. These bits influ-
ence the crypto-algorithm but cannot be read directly.
7
6
5
4
3
8
1
4
EM MICROELECTRONIC-MARIN SA
V4070
Memory Map
Commands
Bit15
Bit0
Crypt Key 80
Crypt Key 95
word 9
COMMAND BITS
FUNCTION
ID-MODE
UM-MODE
Crypt Key 64
8
7
6
5
4
3
2
1
0
Crypt Key 79
0 0 1
0 1 0
0 1 1
1
1
0
Crypt Key 63
Crypt Key 47
Crypt Key 31
Crypt Key 15
ID 31
Crypt Key 48
Crypt Key 32
Crypt Key 16
Crypt Key 0
ID 16
AUTHENTICATION
WRITE WORD
1 0 1
0
First bit Parity bit
Recieved
Figure 6
ID 15
ID 0
UM 16
UM 0
ID Mode
After reception of the command including the parity
the chip sends a header consisting of 12 manchester
coded ‘1’s followed by 4 manchester coded ‘0’s. Then
the chip sends the 32 Bits of ID contained in words 3
and 2 of the EEPROM once, without parity, starting
with the MSB of word 3. After completion the chip
returns to Standby-Mode.
LB1,LB0,UM 29
UM 15
Figure 5
Standby Mode
After a Power-On Reset and upon completion of a
command, the chip will execute the Standby Mode, in
which it will continuously send LIWs to allow the reader
to issue commands. As every LIW has a duration of
160 periods of the RF field the reader can turn to Re-
ceive mode every 1.3ms at 125kHz.
ID Mode
t rID
Header
OUTPUT
INPUT
LIW
11111111111100D31-D LIW
RM Comman
Receive Mode
1 bit - 32 T0 periods
To change from Standby Mode to another operation
the chip has to be brought into Receive Mode. To do
this the Transceiver sends to the chip the RM pattern
during the 32 clocks of modulated phase in a Listen
Window (LIW). The V4070 will stop sending data upon
reception of a valid RM. The RM pattern consists of 2
bits “0” sent by the transceiver. The first “0” is to be
detected during the 32 periods when the modulation
is “ON” in the LIW.
Data
Coded Data
T0 = Period of RF carrier frequency
Figure 7
UM-MODE
In UM-MODE the chip sends LB1 and LB0 followed
by the 30 Bits of UM starting with the MSB following
the same procedure as in ID-MODE. After completion
the chip returns to Standby Mode.
Next the V4070 expects a command to specify the
operation to be executed.
Commands
The commands are composed of 4 bits, divided into 3
data bits and 1 even parity bit (total amount of “1’s” is
even including the parity bit). There exist 4 different
commands. Upon reception of an unknown command
or a command with wrong parity the chip will immedi-
ately return into Standby Mode.
5
EM MICROELECTRONIC-MARIN SA
V4070
Authentication
Begin
In this mode the chip first receives the 56 bits of ran-
dom number followed by seven bits of divergency bits
that the reader should send as “0” followed by 28 Bits
of cipher_1 (f(RN)) as authentication of the lock. The
chip decides if the authentication is accepted. In this
case the V4070 sends a header (12 manchester coded
‘1’s followed by 4 manchester coded ‘0’s). Next 20
Bits of cipher_2 (g(RN)) are sent. Else it sends a sin-
gle NAK.
Receive
RN
(56 Bits)
f(RN)
valid?
N
Y
Divergency
Send
header
Send
NAK
Receive
f(RN)
(28 Bits)
Upon completion of this command the V4070 returns
to Standby Mode.
Send
g(RN)
(20 Bits)
End
Figure 8
Authentication
Tauth
Tdiv
OUTPUT
LIW
RM
Header
g(RN)
LIW
INPUT
Command
RN
“0000000”
f(RN)
Figure 9
Word Organisation
Write Word
The Write Word command is followed by the address
and data. The address consists of a 5 bit block con-
taining 4 data bits and 1 even parity. The data con-
sists of 4 times 5 bit blocks, each block consisting of 4
data bits and 1 associated even parity bit. One addi-
tional block consists of 4 column parity bits and a trail-
ing zero (refer to fig 10).
First bit input
Data Row Even Parity
D15 D14 D13 D12 P3
D11 D10 D09 D08 P2
D07 D06 D05 D04 P1
D03 D02 D01 D00 P0
PC3 PC2 PC1 PC0
0
Column Even Parity
Last bit input
logic "0"
Address
A3 A2 A1 A0 Padd
Figure 11
First bit recieved
After reception of the write command, the address and
the data, the V4070 will check the parity and the Lock-
Bits. If all the conditions are fullfilled, an Acknowledge
pattern (ACK) will be issued, and the EEPROM writ-
ing process will start. At the end of programming the
chip will send anAcknowledge pattern (ACK). If at least
one of the checks fails, the chip will issue a No Ac-
knowledge pattern (NAK) instead of ACK and return
to the Standby Mode.
Data
D15 D14 D13 D12 P3 D11 D10 D09 D08 P2 D07 D06 D05 D04 P1 D03 D02 D01 D00 P0
PC3 PC2 PC1 PC0 "0"
Figure 10
The V4070 might also return to the Standby Mode with-
out sending back a NAK if the incomming data is cor-
rupted and/or inconsistent.
6
EM MICROELECTRONIC-MARIN SA
V4070
Write Word
twee
T
wa
OUTPUT
INPUT
LIW
ACK
ACK
LIW
RM
WRITE WORD ADDRESS
DATA
Figure 12
AC/DC Converter and Voltage Limiter
Write Word
The AC/DC converter is fully integrated on chip and
will extract the power from the incident RF field. The
internal DC voltage will be clamped to avoid high in-
ternal DC voltage in strong RF fields.
Begin
DC Output
Receive
Command
valid ?
N
V
Y
Receive
Address
Send
ACK
Receive
Data
Write
Data
AC Input
Figure 14
Clock Extractor
The Clock extractor will generate a system clock with
a frequency corresponding to the frequency of the RF
field. The system clock is fed into a sequencer to gen-
erate all internal timings.
Send
ACK
Send
NAK
The clock extractor is optimized for power-consump-
tion, sensitivity and noise-suppression. As the input
signal is subject to a large dynamic range due to the
amplitude modulation, the clock-extractor may miss
clocks or add spurious clocks close to the edges of
the RF-envelope. This desynchronisation will not be
larger than ± 1 clocks per Bit and must be taken into
account when developping reader software.
End
Figure 13
Power On Reset
When the V4070 with its attached coil will enter an
electromagnetic field, the built in AC/DC converter will
supply the chip. The DC voltage is monitored and a
Reset signal is generated to initialise the logic. The
power On Reset is also provided in order to make sure
that the chip will start issuing LIWs and be ready to
accept commands with a sufficient DC power level. A
hysteresis is provided to avoid improper operation at
limit level.
Data Extractor
The transceiver generated field will be amplitude modu-
lated to transmit data to the V4070. The Data extrac-
tor demodulates the incomming signal to generate logic
levels, and decodes the incomming data.
Modulator
The Data Modulator is driven by the serial data
outputted from the memory or the Crypto-Logic which
is Manchester encoded. The modulator will draw a
large current from both coil terminals, thus amplitude
modulating the RF field according to the memory data.
7
EM MICROELECTRONIC-MARIN SA
V4070
Communication from Transponder to the Transceiver ( READ MODE)
The V4070 modulates the amplitude of the RF field to transmit data to the transceiver. The data is output
serially from the EEPROM and manchester encoded.
1 bit
32 periods of
RF field
1 bit
1 bit
1 bit
16 periods
Data from
EEPROM
Coded Data
Measured on
the COIL
Figure 15
The V4070 uses different patterns to send status information to the transceiver. Their structure cannot be
confused with a bit pattern sequence. These patterns are the Listen Window (LIW) to inform the transceiver that
data can be accepted, the Acknowledge (ACK) indicating proper communication and end of EEPROM write,
and the No Acknowledge (NAK) when something is wrong.
LIW
ACK
NAK
16 16
64
32
32
16 16
48
16
48
16
16 16
48
16
32
16 16
All numbers represent number of periods of RF field
Figure 16
Communication from the Transceiver to the Trans-
ponder (RECEIVE MODE)
(100% modulation) during the first half of a bit period
(first 16 periods). The transceiver must not turn “OFF”
the field earlier than clock 1 of a bit period. It is recom-
mended to turn “OFF” the field after 4 clocks of the bit
period. The field is stopped from clock 5 to 16 of the
bit period, and then turned “ON” again for the remain-
ing 16 periods.
To ensure synchronisation between the transceiver and
the transponder, a logic bit set to “0” has to be trans-
mitted at regular intervals. The RM pattern consists of
two bits set to “0” thus allowing initial synchronisation.
While the transceiver is sending data to the trans-
ponder, two different modulations will be observed on
both coils. During the first 16 clocks of a bit period, the
V4070 is switching “ON” its modulation device caus-
ing a modulation of the RF field. This modulation can
also be observed on the transceiver’s coil. The trans-
ceiver to send a bit “0” will switch “OFF” the field, and
this 100% modulation will be observed on the trans-
ponder coil.
The V4070 can be switched to the Receive Mode ONLY
DURINGALISTEN WINDOW. The Transceiver is syn-
chronized with the incomming data from the trans-
ponder. During the phase when the chip has its modu-
lator “ON” (32 periods of RF), the transceiver has to
send a bit “0”. At reception of the first “0”, the chip
stops immidiately the LIW sequence and expects then
another bit “0” to switch to receive mode. The trans-
ceiver and the chip are now synchronized and further
data is sent with a bit rate of 32 periods of the RF field.
The V4070 turns “ON” its modulator at the beginning
of each frame of 32 clock periods corresponding to
one bit. To send a logic “1” bit, the transceiver contin-
ues to send clocks without modulation.After 16 clocks,
the modulation device of the V4070 is turned “OFF”
allowing recharge of the internal supply capacitor. To
send a logic “0” bit, the transceiver stops sending clocks
8
EM MICROELECTRONIC-MARIN SA
V4070
Bit Period
DATA :
"1"
"0"
"0"
"1"
"0"
"1"
Transceiver
Coil
Transponder
Coil
Periods of RF field :
16
16
16
16
Modulation induced by the Transponder
Modulation induced by the Transceiver
*
* Recommended : 4 periods
Minimum : 1 period
Figure 17
Package and Ordering Information
Dimensions of PCB Version
Chip Dimensions
3556
V4070
528
8.0
1289
COIL1
COIL2
181
V4070
1803
IC Thickness : 280 µm ± 25 µm
Dimensions in [µm]
1.0
4.0
Dimensions in [mm]
Figure 18
Figure 19
Ordering Information
The V4070 is available in chip form:
without Bumps
PCB
V4070 IC
For sampling, the following version is available:
Other packages available on request.
V4070 - PCB
EM Microelectronic-Marin SA cannot assume responsibility for use of any circuitry described other than circuitry entirely embodied in an
EM Microelectronic-Marin SA product. EM Microelectronic-Marin SA reserves the right to change the circuitry and specifications without
notice at any time. You are strongly urged to ensure that the information given has not been superseded by a more up to date version.
© 1997 EM Microelectronic-Marin SA, 10/97 Rev. A/188
EM Microelectronic-Marin SA CH-2074 Marin, Switzerland,
Tel. +41 32 755 51 11,
Fax. +41 32 755 54 03
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